Archive for the ‘Hot Article’ Category

Hot Article: Construction of high strength hollow fibers by self-assembly of a stiff polysaccharide with short branches in water

Anybody who has spent time working in a chemistry laboratory would be forgiven for being jealous of nature’s ability to reliably prepare functional materials. One of its greatest tricks is the use of intermolecular forces to spontaneously create structures of incredible complexity out of many constituent parts. Recently, a great deal of research has focused on understanding these natural processes with a view to creating new materials unknown to nature.

As well as being inspired by naturally occurring self-assembly processes, Shuqin Xu et al. go one step further and also make use of a naturally occurring molecule – extracted from the commercially available fungus Auricularia auricula-judae. The molecule is a polysaccharide with a relatively hydrophobic backbone and hydrophilic side-chains. This combination of features means that – much like the self-assembly of lipids into bilayers – the chains self-assemble into hollow nanofibres with a hydrophilic surface and hydrophobic core. Fluorescence microscopy revealed these fibres to be several microns long with diameters of less than 100 nm. Furthermore, increasing the concentration of the nanofibres led to self-assembly into high aspect ratio thin films followed by rolling of the films into tubes. This fascinating hierarchical structure is believed to contribute to improved mechanical properties over comparable materials such as glucose.

Construction of high strength hollow fibers by self-assembly of a stiff polysaccharide with short branches in water

J. Mater. Chem. A, 2013, 1, 4198.  DOI:10.1039/C3TA00050H

James Serginson is a guest web writer for the Journal of Materials Chemistry blog. He currently works at Imperial College London carrying out research into nanocomposites.

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Hot Articles for September!

Theranostic magnetic nanoparticles for efficient capture and in situ chemotherapy of circulating tumor cells
Ya Wang, Hui-Zhen Jia, Kai Han, Ren-Xi Zhuoa and Xian-Zheng Zhang


Carbon-sulfur composites for Li-S batteries: status and prospects
Da-Wei Wang, Qingcong Zeng, Guangmin Zhou, Lichang Yin, Feng Li, Hui-Ming Cheng, Ian R. Gentle and Gao Qing Max Lu


Engineering highly efficient Eu(III)-based tri-ureasil hybrids toward luminescent solar concentrators
Mariela M. Nolasco, Patrícia M. Vaz, Vânia T. Freitas, Patrícia P. Lima, Paulo. S. André, Rute A. S. Ferreira, Pedro D. Vaz, Paulo Ribeiro-Claroa and Luís D. Carlos

These papers are free to access until 4th November

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Hot Articles for August!

Crystal structure and chemistry of topological insulators
R. J. Cava, Huiwen Ji, M. K. Fuccillo, Q. D. Gibson and Y. S. Hor

DNA-functionalized silver nanoclusters as a chemopalette: tunable fluorescence for turn-on detection of cysteine
Guoliang Liu, Da-Qian Feng, Xiaoyu Mu, Wenjie Zheng. Tianfeng Chen, Li Qi and Dan Li

A novel polymeric precursor for micro/mesoporous nitrogen-doped carbons
Qiang Zhao, Tim-Patrick Fellinger, Markus Antonietti and Jiayin Yuan
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Hot Article: Transition metal oxide alloys as potential solar energy conversion materials

Transition metal oxide alloys as potential solar energy conversion materials

Although calculating the likelihood that the Sun will rise tomorrow is far from trivial, solar power remains an extremely promising source of sustainable energy. Widespread adoption of current-generation photovoltaics (PV) is held back by low efficiency and the high cost of manufacturing the necessary single-crystal silicon. Inexpensive, naturally occurring transition metal oxides (TMOs) such as iron(II) oxide, manganese(II) oxide and nickel(II) oxide would be cost-effective but they currently suffer from extremely low efficiency.

Toroker and Carter recently attempted to tackle this problem using a computational approach. They simulated the effect that combining different TMOs would have on their usefulness in PV applications. They considered four key properties: band gap, the type of states at band edges, the band edge positions and the band gap centre (BGC) offset – a new metric proposed by the authors. Through the simulations, they found it was possible to prepare more useful materials when using combinations of TMOs. For example, the band gaps of MgO, MnO, NiO and ZnO – which are normally too high to absorb solar energy – could be reduced in an alloy formed with FeO.

Their calculations suggest that an alloy of 3:1 NiO:FeO would satisfy all their criteria for a useful PV. They suggest that the next step in the process is to devise a strategy for doping to improve conductivity.

Transition metal oxide alloys as potential solar energy conversion materials

J. Mater. Chem. A, 2013, 1, 2474.  DOI:10.1039/C2TA00816E

James Serginson is a guest web writer for the Journal of Materials Chemistry blog. He currently works at Imperial College London carrying out research into nanocomposites.

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

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Journal of Materials Chemistry B Paper featured in Materials Views

A paper by Dr Tal Dvir of Tel Aviv University has been featured in Materials Views: Gold nanofibers improve heart function.

This paper reports on the fabrication of new scaffolds for cardiac tissue engineering, featuring the incorporation of gold nanoparticles into a 3D fibrous matrix. Improved connectivity and electrical signalling transfer were observed in cells cultured on the composite biomaterials, compared to cells cultured on scaffolds without nanoparticles. These scaffolds may potentially lead to a new treatment and an improved outcome for patients whose cardiac tissue has been damaged during a heart attack.

The full research paper can be found here:

Nanoengineering gold particle composite fibers for cardiac tissue engineering
Michal Shevach, Ben M. Maoz, Ron Feiner, Assaf Shapira and Tal Dvir

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Hot Article: Electrochemically assisted bacteria encapsulation in thin hybrid sol–gel films

Electrochemically assisted bacteria encapsulation in thin hybrid sol–gel films

Bacteria are typically cast in one of two roles: either vile, disease-causing microkillers evolving faster than science can keep up or as benevolent, yoghurt-borne wardens of the digestive system. An increasingly important third job is that of efficient, microscopic machines capable of producing complex biomolecules such as DNA or insulin, working as biosensors or acting as highly-specific catalysts.

A recent paper by Ghach et al. focuses on encapsulating bacteria in thin silica films in order to make them more practical for use in bioelectronic sensors. They developed two methods of preparing films. Firstly, a two-step process where bacteria were immobilised on an indium tin oxide (ITO) electrode before a silica-based sol was deposited over them. The second method was a one-step where the sol and the bacteria were deposited at the same time (shown above). Trehalose, poly(ethylene glycol) (PEG) and chitosan were also present in the sol to improve cell viability.

Using the two-step process, the researchers found that by varying deposition times it was possible to prepare films with a thickness between 82 nm and 2 μm. With optimum conditions, 95% cell viability was observed after one month. For the one-step process, which resulted in a composite film containing homogeneously dispersed bacteria, it was shown that encapsulated luminescent E. coli still exhibited 50% luminescence after storage for four weeks.

Electrochemically assisted bacteria encapsulation in thin hybrid sol–gel films

J. Mater. Chem. B, 2013, 1, 1052.  DOI:10.1039/C2TB00421F

James Serginson is a guest web writer for the Journal of Materials Chemistry blog. He currently works at Imperial College London carrying out research into nanocomposites.

To keep up-to-date with all the latest research, sign-up to our RSS feed or Table of contents alert.

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July’s Hot Articles!

Asymmetric PSt-EA/Ni-Silicate hollow microsphere with a hierarchical porous shell
Yufeng Zhou, Wanquan Jiang, Shouhu Xuan, Xinglong Gong, Fang Ye, Sheng Wang and Qunling Fang


Revealing the structural properties of hydrogenated black TiO2 nanocrystals
Ting Xia and Xiaobo Chen


The elastic and optical properties of a bent-core thiadiazole nematic liquid crystal: the role of the bend angle
S. Kaur, L. Tian, H. Liu, C. Greco, A. Ferrarini, J. Seltmann, M. Lehmann and H. F. Gleeson

 

These papers are free to access until 27th August!


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June’s Hot Articles!

Design of conductive crown ether based columnar liquid crystals: impact of molecular flexibility and geometry
P. Staffeld, M. Kaller, S. J. Beardsworth, K. Tremel, S. Ludwigs, S. Laschat and F. Giesselmann



A sulfur-assisted strategy to decorate MWCNTs with highly dispersed Pt nanoparticles for counter electrode in dye-sensitized solar cells
Jian Wei Guo, Bo Zhang, Yu Hou, Shuang Yang, Xiao Hua Yang and Hua Gui Yang



Efficient catalytic conversion of ammonia borane to borazine and its use for hexagonal boron nitride (white graphene)
Sung-Kwan Kim, Hyunjin Cho, Myung Jong Kim, Hee-Jun Lee, Jin-hyung Park, Young-Boo Lee, Hwan Chul Kim, Chang Won Yoon, Suk Woo Nam and Sang Ook Kang

These papers are free to access until 16th July!


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Taking the shine off: Journal of Materials Chemistry A article in Chemistry World

Painting used to test method with a white dot to show test area (left). Test area before (middle) and after (right) cleaning

Painting restoration could be yet another application for ionic liquids, new research shows. The work paves the way to safer procedures for cleaning paintings.

Over time, varnish applied to the top of oil paintings tends to yellow and accumulate dirt. Current conservation methods involve cleaning paintings with organic solvents but these pose environmental and health risks. Now, researchers in Portugal have demonstrated that using ionic liquids is a less toxic way to remove varnishes from paintings.

Read the full article by Jess Cocker in Chemistry World

Varnish removal from paintings using ionic liquids
Maria Filipa Pacheco, Ana Isabel Pereira, Luís C. Branco and A. Jorge Parola
J. Mater. Chem. A, 2013, Advance Article
DOI: 10.1039/C3TA10679A

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Hot Article: The reaction between Nafion sulfonyl fluoride precursor membrane and 1,4-dimethylpiperazine does not yield reliable anion-exchange membranes

Alkaline polymer electrolyte fuel cells (APEFCs) have received much attention as next generation, platinum free fuel cells for future energy applications. A significant challenge to the development of APEFCs is the fabrication of suitable anion-exchange membranes (AEMs) for use within the fuel cells.  Recently, a synthesis based on the reaction of Nafion® sulfonyl fluoride membranes with diamine 1, 4-dimethylpiperazine has been proposed as a method for making AEMs.

In this Hot Article, Varcoe and co-workers investigate the Nafion-based systems using a combination of vibration spectroscopy, solid state NMR and measurement of ion exchange capabilities.  They find strong evidence that membranes synthesised by the reported procedure are predominantly in the cation-exchange form. These findings suggest that, contrary to previous reports, the membranes are not suitable for use in electrochemical devices requiring anion exchange polymer electrolytes, such as APEFCs.

The reaction between Nafion sulfonyl fluoride precursor membrane and 1, 4-dimethylpiperazine does not yield reliable anion-exchange membranes

J. Mater. Chem. A, 2013,1, 1018-1021 DOI: 10.1039/C2TA00955B

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